Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We have used the facility provided by the NINDS/NIMH Microarray Consortium to identify genes that show abnormal expression patterns in these mice. We would like to compare these changes with that opccured in SOD1 mice, a mouse model of motor neuron diseases. Analysis of these genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from motor neurons of wild type and SOD1 mice to identify genes that show abnormal expression patterns, which may be implicated in the death of SOD1 mice and shared with the same changes in NR3B-null mice. We hypothesize that genes with their transcription level changing significantly by ablation of NR3B will be associated with the molecular mechanism underlying the death of motor neurons in NR3B null mice. As NR3B is expressed primarily in the motor neurons of hindbrain and spinal cord, we have first collected and analyzed the spinal cord samples from NR3B null mice and wild-type controls in P4, an age of disease onset. We like to compare motor neuron and spinal cord smaples from SOD1 mice at the age prior to the disease onset. Total RNA from total 12 samples will be purified from ~200 motor neurons obtained by Laser Capture Microdissection and the total spinal cord. Extracted RNAs will be subjected to one or two rounds of amplification and the obtained cRNA will be biotinylated. The purified cRNA will be sent to the NINDS/NIMH Microarray Consortium be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will first identify genes that show significant changes between wild-type and SOD1 mice and then compare that with the result from NR3B null mice. Keywords: dose response

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We have used the facility provided by the NINDS/NIMH Microarray Consortium to identify genes that show abnormal expression patterns in these mice. We would like to compare these changes with that opccured in SOD1 mice, a mouse model of motor neuron diseases. Analysis of these genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from motor neurons of wild type and SOD1 mice to identify genes that show abnormal expression patterns, which may be implicated in the death of SOD1 mice and shared with the same changes in NR3B-null mice. We hypothesize that genes with their transcription level changing significantly in SOD1 mutant mice will be associated with the molecular mechanism underlying the death of motor neurons. We like to compare motor neuron and spinal cord smaples from SOD1 mice at the age prior to the disease onset. Total RNA from total 9 samples will be purified, each from ~200 motor neurons obtained by Laser Capture Microdissection and the total spinal cord. Extracted RNAs will be subjected to one or two rounds of amplification and the obtained cRNA will be biotinylated. The purified cRNA will be sent to the NINDS/NIMH Microarray Consortium be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will first identify genes that show significant changes between wild-type and SOD1 mice and then compare that with the result from NR3B null mice.

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We have used the facility provided by the NINDS/NIMH Microarray Consortium to identify genes that show abnormal expression patterns in these mice. We would like to compare these changes with that opccured in SOD1 mice, a mouse model of motor neuron diseases. Analysis of these genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from motor neurons of wild type and SOD1 mice to identify genes that show abnormal expression patterns, which may be implicated in the death of SOD1 mice and shared with the same changes in NR3B-null mice. We hypothesize that genes with their transcription level changing significantly by ablation of NR3B will be associated with the molecular mechanism underlying the death of motor neurons in NR3B null mice. As NR3B is expressed primarily in the motor neurons of hindbrain and spinal cord, we have first collected and analyzed the spinal cord samples from NR3B null mice and wild-type controls in P4, an age of disease onset. We like to compare motor neuron smaples from SOD1 mice at the age around the disease onset. Total RNA from total 6 samples will be purified from ~200 motor neurons obtained by Laser Capture Microdissection. Extracted RNAs will be subjected to two rounds of amplification and the obtained cRNA will be biotinylated. The purified cRNA will be sent to the NINDS/NIMH Microarray Consortium be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will first identify genes that show significant changes between wild-type and SOD1 mice and then compare that with the result from NR3B null mice.

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We have used the facility provided by the NINDS/NIMH Microarray Consortium to identify genes that show abnormal expression patterns in these mice. We would like to compare these changes with that opccured in SOD1 mice, a mouse model of motor neuron diseases. Analysis of these genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from motor neurons of wild type and SOD1 mice to identify genes that show abnormal expression patterns, which may be implicated in the death of SOD1 mice and shared with the same changes in NR3B-null mice. We hypothesize that genes with their transcription level changing significantly by ablation of NR3B will be associated with the molecular mechanism underlying the death of motor neurons in NR3B null mice. As NR3B is expressed primarily in the motor neurons of hindbrain and spinal cord, we have first collected and analyzed the spinal cord samples from NR3B null mice and wild-type controls in P4, an age of disease onset. We like to compare motor neuron smaples from SOD1 mice at the age around the disease onset. Total RNA from total 6 samples will be purified from ~200 motor neurons obtained by Laser Capture Microdissection. Extracted RNAs will be subjected to two rounds of amplification and the obtained cRNA will be biotinylated. The purified cRNA will be sent to the NINDS/NIMH Microarray Consortium be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will first identify genes that show significant changes between wild-type and SOD1 mice and then compare that with the result from NR3B null mice. Keywords: other

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We have used the facility provided by the NINDS/NIMH Microarray Consortium to identify genes that show abnormal expression patterns in these mice. We would like to compare these changes with that opccured in SOD1 mice, a mouse model of motor neuron diseases. Analysis of these genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from motor neurons of wild type and SOD1 mice to identify genes that show abnormal expression patterns, which may be implicated in the death of SOD1 mice and shared with the same changes in NR3B-null mice. We hypothesize that genes with their transcription level changing significantly in SOD1 mutant mice will be associated with the molecular mechanism underlying the death of motor neurons. We like to compare motor neuron and spinal cord smaples from SOD1 mice at the age prior to the disease onset. Total RNA from total 9 samples will be purified, each from ~200 motor neurons obtained by Laser Capture Microdissection and the total spinal cord. Extracted RNAs will be subjected to one or two rounds of amplification and the obtained cRNA will be biotinylated. The purified cRNA will be sent to the NINDS/NIMH Microarray Consortium be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will first identify genes that show significant changes between wild-type and SOD1 mice and then compare that with the result from NR3B null mice. Keywords: other

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We would like to use the facility provided by the NINDS/NIMH Microarray Consortium to identify true outlier genes that show abnormal expression patterns in these mice. Analysis of these outlier genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from the hindbrain and spinal cord of wild type and NR3B null mice to identify true outlier genes that show abnormal expression patterns, which may be implicated in the death of NR3B-null mice; We hypothesize that genes with their transcription level changing significantly by ablation of NR3B will be associated with the molecular mechanism underlying the death of motor neurons in NR3B null mice. As NR3B is expressed primarily in the hindbrain and spinal cord, we will first collect and analyze the hindbrain and spinal cord samples from NR3B null mice and wild-type controls in triplicate at two time points (P0 and P5). Total RNA from total 12 samples will be purified. Extracted RNAs will be treated for with DNase I to remove contaminating genomic DNA. The purified RNA will be sent to the NINDS/NIMH Microarray Consortium to generate biotin-labeled probe according to the Affymetrix protocol. These probes will be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will use computer software, GeneSpring (Silicon Genetics, Redwood City, CA), to analyze data from microarray experiments. We will first identify genes that show significant changes between wild-type and NR3B null mice by applying ANOVA analysis to sample groups of different ages. The genes identified in this manner will then be subjected to hierarchical (Gene tree) and nonhierarchical (K-means) cluster analysis, in order to group them according to similar expression patterns. Another clustering method, the self-organizing map, will be used to determine whether one gene cluster is a variant of another. Finally, the Principal Components Analysis (PCA) will be employed to analyze large sample groups, which may include experimental variability with respect to age, anatomical location and genotype. We will determine from these analysis whether further experiments are needed using different array platforms, such as Agillent Oligo Array.

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We would like to use the facility provided by the NINDS/NIMH Microarray Consortium to identify true outlier genes that show abnormal expression patterns in these mice. Analysis of these outlier genes will help to identify changes in networks and pathways that may cause the death of NR3B-null mice. These studies will further help to elucidate the functional role of NR3B in motor neurons. We will compare samples from the hindbrain and spinal cord of wild type and NR3B null mice to identify true outlier genes that show abnormal expression patterns, which may be implicated in the death of NR3B-null mice We hypothesize that genes with their transcription level changing significantly by ablation of NR3B will be associated with the molecular mechanism underlying the death of motor neurons in NR3B null mice. As NR3B is expressed primarily in the hindbrain and spinal cord, we will first collect and analyze the hindbrain and spinal cord samples from NR3B null mice and wild-type controls in triplicate at two time points (P0 and P5). Total RNA from total 12 samples will be purified. Extracted RNAs will be treated for with DNase I to remove contaminating genomic DNA. The purified RNA will be sent to the NINDS/NIMH Microarray Consortium to generate biotin-labeled probe according to the Affymetrix protocol. These probes will be used to hybridize the GeneChip Mouse Genome 430 2.0 Array. The hybridization, scanning, and initial data analysis of these GeneChips will be conducted by the Consortium staff. We will analyze the collected data further after data collection. We will use computer software, GeneSpring (Silicon Genetics, Redwood City, CA), to analyze data from microarray experiments. We will first identify genes that show significant changes between wild-type and NR3B null mice by applying ANOVA analysis to sample groups of different ages. The genes identified in this manner will then be subjected to hierarchical (Gene tree) and nonhierarchical (K-means) cluster analysis, in order to group them according to similar expression patterns. Another clustering method, the self-organizing map, will be used to determine whether one gene cluster is a variant of another. Finally, the Principal Components Analysis (PCA) will be employed to analyze large sample groups, which may include experimental variability with respect to age, anatomical location and genotype. We will determine from these analysis whether further experiments are needed using different array platforms, such as Agillent Oligo Array. Keywords: time-course

Project description:Microarray analysis has been applied to the study of ALS in order to investigate gene expression in whole spinal cord homogenates of SOD1 G93A mice and human ALS cases, although the massive presence of glial cells and inflammatory factors has made it difficult to define which gene expression changes were motor neuron specific. Recently, laser capture microdissection (LCM), combined with microarray analysis, has allowed the identification of motor neuron specific changes in gene expression in human ALS cases. The aim of the present study is to combine LCM and microarray analysis to study how motor neurons in the spinal cord of transgenic SOD1 G93A mice and transgenic SOD1 WT respond to stimuli determined by the presence of the human mutant protein throughout the evolution of the stages in motor neuron injury Experiment Overall Design: Motor neurons have been isolated from the spinal cord of G93A mice and non transgenic littermates at different time points and the transcription expression profile of the isolated motor neurons has been analysed

Project description:In our original grant we proposed to use the NR3B-null mouse model to study the role of NR3B subunit in motor neuron function. We have now successfully generated NR3B null mice. Interestingly, NR3B-null mice invariably die at age P4-P8. Our preliminary examination indicates that the motor strength of these mice is severely impaired prior to death. As we continue to explore the cause of death in NR3B null mice, we propose to conduct gene profiling experiments to search for transcription changes in the brain related to ablation of the NR3B gene. We have previously used the UCLA array facility provided by the NINDS/NIMH Microarray Consortium to identify genes that show abnormal expression patterns in these mice using whole brain samples. Now, we would like to use the same approach to analyze pure motor neuron samples obtained by Laser Capture Microdisection (LCM). As these samples are of small size we need to use RNA amplification method. We would like to compare probes from two amplification methods to see which one gives the best result. We will collect the cDNA probe obtained by RNA-based single primer isothermal amplification developed by Nugen, Inc. and the aRNA probe obtained from T7-based RNA amplification. Both the hybridization intensity and the percentage of the present call of these two types of probe will be analyzed. The cDNA probe obtained by RNA-based single primer isothermal amplification developed by Nugen, Inc. may have some advantage over the aRNA probe obtained from T7-based RNA amplification. Two samples will be processed by either RNA-based single primer isothermal amplification developed by Nugen or T7-based RNA amplification to obtain cDNA or aRNA probes, respectively. For each sample we will use 600 motor neurons obtained by LCM. Both types of probe will be labeled by biotin and hybridize to Affymetrix GeneChip Mouse Genome 430 2.0 Array. Data analysis will be performed by array facility.

Project description:Missense mutations in the gene for the ubiquitously expressed superoxide dismutase-1 (SOD1) are one of the causes of familial amyotrophic lateral sclerosis (ALS), the most common adult onset motor neuron disease in humans killing selectively large motor neurons. Mice and rats overexpressing mutant SOD1 develop an adult onset neurodegenerative disease with hindlimb-paralysis and subsequent death similar to the human condition. In order to analyze the effects of mutant SOD1 expression onto the most affected cell-type in ALS, a small subpopulation of spinal cord cells, we propose to use laser microdissection to isolate mouse lumbar motor neurons and to assess the changes onto the mRNA expression profile using Affymetrix GeneChips compared to control animals. While two studies applying a genomic approach on the ALS mouse models used the entire spinal cord, contributions of changes to motor neurons were masked by the inflammatory effects of mutant SOD1 and the much larger population of non-motor neuronal cells. What is therefore needed is a cell-type specific expression profile that could reveal dysregulations in the transcriptome of the affected motor neurons. In order to find and analyze disease relevant gene expression profile changes in the mutant vs. the wildtype overexpressing SOD1 mice, we propose to use two different mutant SOD1 lines. Both lines develop the same ALS-like motor neuron disease, however, line 1 (with a G37R mutation) retains the full activity of the SOD1 enzyme while line 2 (with a G85R mutation) has almost no SOD1 enzymatic activity. We believe that by using these two most extreme variants of ALS-inducing mutant SOD1 forms, candidate genes that will be similarly dysregulated in both mutant lines will have great potential to be a disease relevant hit. We will collect from both mutant SOD1 mouse lines lumbar motor neurons from three presymptomatic timepoints, equally distributed during their adult life and before obvious hindlimb-weakness or paralysis signs and compare them to two control lines, negative littermates and wildtype SOD1 overexpressing mice. Furthermore, to determine if their are already mutant SOD1-induced changes since the formation of the affected cells, we will also isolate embryonic spinal cord motor neurons and compare them between mutant SOD1 and wildtype SOD1 overexpressing animals. Both, mice deleted in wildtype SOD1 and mice overexpressing mutant human SOD1 clearly established that the toxic property of mutant SOD1 is based upon a gain-of-toxic function phenomenon rather than a loss-of-function effect, since the SOD1 knock-out mice are overall normal. Furthermore, mice overexpressing wildtype SOD1 are healthy and serve as ideal control animals. Therefore, one of the most important question in ALS is to determine what slowly acting mechanism, or build-up of toxic products is responsible for ultimately killing more than 50-70% of the large lumbar spinal cord motor neurons. We hypothezise that the toxic property of mutant SOD1 must already induce changes onto the transcriptome of the most at-risk cell-type, the large lumbar spinal cord motor neuron, very early on in the presymptomatic phase of the disease course, when the animal is still without any paralysis signs and moving normally around the cage. We will choose 3 timepoints before phenotypic disease-onset that is at 22 weeks for the SOD1G37R line (L42) and at 11 months for the SOD1G85R line (L148). The timepoints are 8, 15 and 18 weeks for SOD1G37R line and 4, 7.5 and 9 months for the SOD1G85R line all compared to age-matched control animals (wildtype SOD1 overexpressing mice (L76) for the SOD1G37R line (high mutant SOD1 levels) and negative littermates for the SOD1G85R line (low mutant SOD1 levels)). Using the Leica lasermicrodissection system on fresh frozen spinal cord sections, we process a single spinal cord sample in 3 days resulting in approximately 4000 ventral horn motor neurons collected from 150 consecutive 20 um sections of the most affected lumbar spinal cord region (L4-L6). To visualize the motor neurons, we have established a fast Nissel-staining protocol that is optimized for speed to preserve the integrity of the RNA. Before lasermicrodissection slides containing 5 spinal cord sections are dessicated for 1 hour and samples are collected directly into RNA-preserving lysis-buffer. Using Stratagene's NanoPrep RNA-extraction columns a yield of around 150 ng of total RNA was obtained (Ribogreen-quantification), that is enough for both the 2-round linear RNA amplification and for future candidate confirmation studies using real-time PCR analysis. We are using the Affymetrix Two-Cycle 3'-Amplification Kit, starting with 100 ng of total RNA and will hybridize on Affymetrix Mouse 430 2.0 GeneChips. Embryonic motor neurons are isolated from e14 mutant SOD1G93A overexpressing rat embryos and compared to wildtype SOD1 overexpressing embryos using a metrazimide gradient followed by a p75-antibody purification in combination with magnetic beads. Cells from one litter of embryos were directly collected into lysis-buffer, yielding at least 200-500 ng of total RNA, enough for one Rat 230 2.0 GeneChip (2-round amplification using 100 ng total RNA). Keywords: time-course